Semiconductor module

ABSTRACT

A semiconductor module according to an embodiment includes an insulating substrate having a power conversion circuit mounted thereon, a first transistor constituting an upper arm, a second transistor constituting a lower arm, a first input interconnection pattern coupled to a positive-side input terminal, a second input interconnection pattern coupled to a negative-side input terminal, an output interconnection pattern coupled to an output terminal, and an absorbing device configured to absorb surge voltage, wherein the first input interconnection pattern includes a first-transistor mounting area on which the first transistor is mounted, wherein the output interconnection pattern includes a second-transistor mounting area on which the second transistor is mounted, wherein the second input interconnection pattern includes an absorbing-device connecting area disposed between the first and second transistor mounting areas, and wherein the absorbing-device connecting area is electrically coupled to the first-transistor mounting area through the absorbing device.

TECHNICAL FIELD

The disclosures herein relate to a semiconductor module.

The present application claims priority based on Japanese applicationNo. 2016-051414 filed on Mar. 15, 2016, the entire contents of which arehereby incorporated by reference.

BACKGROUND ART

It is known that in a semiconductor module having a power conversioncircuit such as an inverter circuit, surge voltage occurs between thepositive-side input terminal and the negative-side input terminal of thepower conversion circuit immediately after turning on or offswitching-element transistors constituting the upper arm and the lowerarm. In order to reduce the surge voltage, a snubber capacitor servingas a surge voltage absorbing device is placed between the positive-sideinput terminal and the negative-side input terminal in Patent Document1.

RELATED-ART DOCUMENTS Patent Document [Patent Document 1] JapanesePatent Application Publication No. 2015-135895 SUMMARY OF THE INVENTION

A semiconductor module according to an aspect of the present disclosuresis a semiconductor module including a power conversion circuit, andincludes an insulating substrate, a first transistor constituting anupper arm of the power conversion circuit, a second transistorconstituting a lower arm of the power conversion circuit andelectrically series-coupled to the first transistor, a first inputinterconnection pattern disposed on the insulating substrate and coupledto a positive-side input terminal for supplying positive power to thepower conversion circuit, a second input interconnection patterndisposed on the insulating substrate and coupled to a negative-sideinput terminal for supplying negative power to the power conversioncircuit, an output interconnection pattern disposed on the insulatingsubstrate and coupled to an output terminal for outputting output powerof the power conversion circuit, and an absorbing device configured toabsorb surge voltage in the power conversion circuit, wherein the firstinput interconnection pattern includes a first-transistor mounting areaon which the first transistor is mounted, wherein the outputinterconnection pattern includes a second-transistor mounting area onwhich the second transistor is mounted, wherein the second inputinterconnection pattern includes an absorbing-device connecting areathat is disposed between the first-transistor mounting area and thesecond-transistor mounting area, and wherein the absorbing-deviceconnecting area is electrically coupled to the first-transistor mountingarea through the absorbing device.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is a plan view illustrating a schematic configuration of asemiconductor module according to an embodiment.

FIG. 2 is a schematic diagram of a configuration on an insulatingsubstrate of the semiconductor module illustrated in FIG. 1.

FIG. 3 is a schematic diagram of a cross-sectional configuration alongthe line in FIG. 1.

FIG. 4 is a plan view illustrating a schematic configuration of anotherexample of the semiconductor module.

FIG. 5 is a schematic diagram of a configuration on an insulatingsubstrate of the semiconductor module illustrated in FIG. 4.

FIG. 6 is a plan view illustrating a schematic configuration of yetanother example of the semiconductor module.

FIG. 7 is a plan view illustrating a schematic configuration of stillanother example of the semiconductor module.

FIG. 8 is a schematic diagram of a configuration on an insulatingsubstrate of the semiconductor module illustrated in FIG. 7.

FIG. 9 is a drawing illustrating an equivalent circuit of thesemiconductor module illustrated in FIG. 1.

MODE FOR CARRYING OUT THE INVENTION

In the technology disclosed in Patent Document 1, the part on which thetransistors are mounted and the part on which the snubber capacitor ismounted are separately formed on the substrate on which theswitching-element transistors or the like are mounted, thereby thermallyseparating these parts from each other, in order to prevent degradationcaused by heat from the snubber capacitor (i.e., surge voltage absorbingdevice). In such a case, the distance between the transistors and thesnubber capacitor tends to be elongated, which may result in the failureto sufficiently reduce surge voltage.

Accordingly, one of the objects of the present disclosures is to providea semiconductor module that is capable of reducing surge voltage morereliably.

In the following, embodiments of the technology of the presentdisclosures will be described with reference to the accompanyingdrawings. In the description of the drawings, the same elements arereferred to by the same numerals, and a duplicate description will beomitted.

Description of Embodiments

In the following, embodiments of the disclosed technology will be listedand described.

A semiconductor module according to an aspect of the present disclosuresis a semiconductor module including a power conversion circuit, andincludes an insulating substrate, a first transistor constituting anupper arm of the power conversion circuit, a second transistorconstituting a lower arm of the power conversion circuit andelectrically series-coupled to the first transistor, a first inputinterconnection pattern disposed on the insulating substrate and coupledto a positive-side input terminal for supplying positive power to thepower conversion circuit, a second input interconnection patterndisposed on the insulating substrate and coupled to a negative-sideinput terminal for supplying negative power (e.g., negative voltage) tothe power conversion circuit, an output interconnection pattern disposedon the insulating substrate and coupled to an output terminal foroutputting output power of the power conversion circuit, and anabsorbing device configured to absorb surge voltage in the powerconversion circuit, wherein the first input interconnection patternincludes a first-transistor mounting area on which the first transistoris mounted, wherein the output interconnection pattern includes asecond-transistor mounting area on which the second transistor ismounted, wherein the second input interconnection pattern includes anabsorbing-device connecting area that is disposed between thefirst-transistor mounting area and the second-transistor mounting area,and wherein the absorbing-device connecting area is electrically coupledto the first-transistor mounting area through the absorbing device.

In the above-noted configuration, the absorbing-device connecting areaof the second input interconnection pattern coupled to the negative-sideinput terminal is situated between the first-transistor mounting area ofthe first input interconnection pattern coupled to the positive-sideinput terminal and the second-transistor mounting area of the outputinterconnection pattern coupled to the output terminal. Thefirst-transistor mounting area has the first transistor mounted thereonthat constitutes an upper arm of the power conversion circuit, and thesecond-transistor mounting area has the second transistor mountedthereon that constitutes a lower arm of the power conversion circuit.The first-transistor mounting area and the absorbing-device mountingarea are coupled through the absorbing device. In such an arrangementand such an interconnection configuration, the absorbing device can besituated close to the first transistor and to the second transistor. Asa result, the wire inductance of the current path through which currentgenerated immediately after the turning on or turning off of each of thefirst transistor and the second transistor flows is lowered, whichenables effective reduction of surge voltage.

The second input interconnection pattern may include a condenserconnecting area seamlessly connected to an end of the absorbing-deviceconnecting area, and the absorbing-device connecting area and thecondenser connecting area may be disposed on the insulating substratesuch as to surround the first-transistor mounting area. The condenserconnecting area may be electrically coupled to the first-transistormounting area through a condenser.

In this case, the condenser connecting area of the second inputinterconnection pattern and the first-transistor mounting area areelectrically coupled through the condensers, so that the voltage (e.g.,direct-current voltage) applied to the series-connected firsttransistors and second transistors can be stabilized.

According to an embodiment, the semiconductor module may further includean auxiliary pattern disposed on the insulating substrate between theabsorbing-device connecting area and the first-transistor mounting area,wherein the absorbing device may include a first circuit element and asecond circuit element, wherein the first circuit element mayelectrically couple the auxiliary interconnection pattern and thefirst-transistor mounting area, and wherein the second circuit elementmay electrically couple the auxiliary interconnection pattern and theabsorbing-device connecting area.

The first circuit element and the second circuit element may becondensers. There is a tendency for the withstanding voltage of acondenser to lower as the capacitance increases. Provision of the firstcircuit element and the second circuit element to couple the first inputinterconnection pattern and the second input interconnection through thethird auxiliary pattern secures voltage tolerance while ensuring thatthe absorbing device has a sufficient capacitance to reduce surgevoltage. The first circuit element and the second circuit element may besuch that one is a resistor and the other is a condenser, for example.In this case, the absorbing device serves as an RC snubber element.

According to an embodiment, the semiconductor module may include aplurality of noted first transistors, and a plurality of noted secondtransistors, wherein the plurality of first transistors may be mountedon the first-transistor mounting area, and may electrically be coupledin parallel, and wherein the plurality of second transistors may bemounted on the second-transistor mounting area, and may electrically becoupled in parallel.

In this case, a plurality of absorbing devices may be provided, and maybe disposed at spaced intervals.

The arrangement of the absorbing devices at spaced intervals enableseach absorbing device to be disposed in close physical proximity to acorresponding one of the first transistors and the second transistors.This arrangement can reduce surge voltage more effectively.

A semiconductor module according to a further aspect of the presentdisclosures include an insulating substrate, a first transistorconstituting an upper arm of a power conversion circuit, a secondtransistor constituting a lower arm of the power conversion circuit, afirst input interconnection pattern being a flat conductive platedisposed on the insulating substrate, the first input interconnectionpattern having the first transistor mounted thereon and beingelectrically coupled to a first end of the first transistor, an outputinterconnection pattern being a flat conductive plate disposed on theinsulating substrate, the output interconnection pattern having thesecond transistor mounted thereon and being electrically coupled to afirst end of the second transistor, a second input interconnectionpattern disposed on the insulating substrate and arranged at a positionbetween the first input interconnection pattern and the outputinterconnection pattern, an interconnection electrically coupling asecond end of the first transistor and the output interconnectionpattern to each other, an interconnection electrically coupling a secondend of the second transistor and the second input interconnectionpattern to each other, and a capacitive device connected between thefirst input interconnection pattern and the second input interconnectionpattern.

In the above configuration, the second input interconnection pattern issituated at a position between the first input interconnection patternhaving the first transistor mounted thereon and the outputinterconnection pattern having the second transistor mounted thereon,with the capacitive device being connected between the first inputinterconnection pattern and the second input interconnection pattern.This configuration enables the capacitive device to be situated close tothe first transistor and to the second transistor. As a result, the wireinductance of a respective current path between the absorbing device andeach of the first transistor and the second transistor is lowered, whichserves to reduce surge voltage efficiently.

Details of Embodiments

In the following, specific examples of the embodiments of the disclosedtechnology will be described with reference to the drawings. The presentinvention is not limited to those examples, and is intended to bedefined by the scope of the claims and to include any variations andmodifications falling within the scope warranted for equivalents of thescope of the claims. In the description of the drawings, the sameelements are referred to by the same numerals, and a duplicatedescription will be omitted.

A semiconductor module 1 schematically illustrated in FIG. 1 and FIG. 2serves as a power conversion apparatus such as an inverter device. Thesemiconductor module 1 includes a plurality of transistors Tr, aninsulating substrate 10, a P pad (i.e., first input interconnectionpattern) 21, an O pad (i.e., output interconnection pattern) 22, an Npad (i.e., second input interconnection pattern) 23, and a plurality ofsurge voltage absorbing devices 30 (which will hereinafter be referredto simply as “absorbing devices”).

The semiconductor module 1 may include a first control pad 24 and asecond control pad 25. The semiconductor module 1 may include a firstauxiliary pad 26 and a second auxiliary pad 27. The semiconductor module1 may include a plurality of diodes Di. Further, the semiconductormodule 1 may include a case 40 for storing the insulating substrate 10as well as the transistors Tr and interconnection structurestherebetween mounted on the insulating substrate 10. In FIG. 1, the case40 is schematically illustrated in dashed lines. The case 40 is made ofa resin, for example. The structure (i.e., pads such as the P pad 21 andthe O pad 22, the transistors Tr, and wires or the like forinterconnections therebetween) on the insulating substrate 10 stored inthe case 40 is embedded in silicone gel, for example.

In the following, unless otherwise indicated, a description will begiven of the embodiment in which the semiconductor module 1 includes thefirst control pad 24, the second control pad 25, the first auxiliary pad26, the second auxiliary pad 27, the diodes Di, and the case 40. In thedescriptions, two directions perpendicular to the thickness direction ofthe insulating substrate 10 may sometimes be referred to as the Xdirection and the Y direction, as illustrated in FIG. 1. The X directionand the Y direction are perpendicular to each other.

The plurality of transistors Tr are mounted on the insulating substrate10. The transistors tr, which are vertical transistors, include a firstupper electrode SP, a second upper electrode GP, and a lower electrodeDP (see FIG. 3) as illustrated in FIG. 1, FIG. 2, and FIG. 3. In FIG. 3,graphic illustration is omitted with respect to an O terminal 52, asecond control terminal 55, and a second auxiliary terminal 57, whichwill be described later. The first upper electrode SP and the lowerelectrode DP are the first main electrode and the second main electrode,respectively, for supplying voltage to the transistors Tr. The secondupper electrode GP is the control electrode for supplying a controlsignal (or a control voltage) to the transistors Tr. The conductivestate of each transistor Tr between the first upper electrode SP and thelower electrode DP is controlled in response to the control signalapplied to the second upper electrode GP. With this arrangement, thetransistors Tr serve as switching elements. The transistors Tr mayalternatively be lateral transistors.

Examples of the material of the transistors Tr include Si andwide-bandgap semiconductors such as SiC and GaN. Examples of thetransistors Tr include a MOSFET (i.e., metal-oxide-semiconductorfield-effect transistor) and an insulated-gate bipolar transistor (i.e.,IGBT).

In the case of the transistors Tr being MOSFETs, the first upperelectrode SP, the second upper electrode GP, and the lower electrode DPcorrespond to the source electrode, the gate electrode, and the drainelectrode, respectively. In the case of the transistors Tr being IGBTs,the first upper electrode SP, the second upper electrode GP, and thelower electrode DP correspond to the emitter electrode, the gateelectrode, and the collector electrode, respectively. In the following,the transistors Tr are MOSFETs, unless otherwise indicated.

The plurality of transistors Tr are electrically coupled to form a powerconversion circuit 2. In the present embodiment, the power conversioncircuit 2 is a single-phase inverter circuit. In this case, thesemiconductor module 1 is a 2-in-1-type semiconductor module, forexample. Among the plurality of transistors Tr, the transistors Trconstituting the upper arm of the power conversion circuit 2 arereferred to as first transistors Tr1, and the transistors Trconstituting the lower arm are referred to as second transistors Tr2.The present embodiment is directed to an example in which thesemiconductor module 1 has three first transistors Tr1 and three secondtransistors Tr2. However, the number of first transistors Tr1 and thenumber of second transistors Tr2 are not limited to three.

The plurality of diodes Di, which are mounted on the insulatingsubstrate 10, serve as freewheeling diodes in the power conversioncircuit 2. The plurality of diodes Di include first diodes Di1corresponding to the first transistors Tr1 and second diodes Di2corresponding to the second transistors Tr2. The number of first diodesDi1 may be equal to the number of first transistors Tr1, for example.Similarly, the number of second diodes Di2 may be equal to the number ofsecond transistors Tr2.

The insulating substrate 10 is a ceramic substrate, for example.Examples of the material of the insulating substrate 10 include AlN,SiN, and Al₂O₃. The insulating substrate 10 as viewed in the thicknessdirection is not limited to a particular shape. Examples of the shape ofthe insulating substrate 10 include a rectangle and a square. The backface of the insulating substrate 10 (which is opposite the face on whichthe first transistors Tr1 and the second transistors Tr2 are mounted)may have a heat sink layer formed thereon made of copper or the like.

In the following, the configuration on the insulating substrate 10 willbe described by mainly referring to FIG. 2.

The P pad 21, which is mounted on the insulating substrate 10 asillustrated in FIG. 2, is an electrode pattern (or interconnectionpattern) for supplying positive power (e.g., positive voltage) to thepower conversion circuit 2. An example of the material of the P pad 21is copper. The P pad 21 includes a first area (first transistor mountingarea) 211 and a second area 212. In FIG. 2, the boundary between thefirst area 211 and the second area 212 is shown by a dash-and-two-dotline for illustrative purposes. This also applies to other drawings(e.g., FIG. 1).

The first area 211 of the P pad 21 is the area on which the plurality offirst transistors Tr1 and the first diodes Di1 provided in one-to-onecorrespondence with the first transistors Tr1 are mounted. It sufficesfor the first area 211 to have an area of sufficient size for mountingthe plurality of first transistors Tr1 and the plurality of first diodesDi1. The first area 211 is not limited to a particular shape, and may bea quadrilateral such as a rectangle or a square.

Each first transistor Tr1 is mounted on the first area 211 such that thelower electrode DP and the first area 211 face each other, and areelectrically coupled to each other. Each first diode Di1 is mounted onthe first area 211 such that the cathode CP and the first area 211 faceeach other, and are electrically coupled to each other. The lowerelectrode DP and the cathode CP may be fixedly mounted to the first area211 through solder or sintered material, for example.

The arrangement of the first transistors Tr1 and the first diodes Di1 onthe first area 211 is not limited to a particular arrangement. Forexample, the plurality of first transistors Tr1 may be aligned in the Ydirection as illustrated in FIG. 2, and the first diodes Di1 may bedisposed alongside the respective first transistors Tr1 on the sidetoward the O pad 22.

The second area 212 of the P pad 21 is the area to which a P terminal(i.e., positive-side input terminal) 51 for supplying positive power tothe semiconductor module 1 is coupled. One end of the P terminal 51 maybe fixedly mounted to the second area 212 through solder or sinteredmaterial, for example. The other end of the P terminal 51, which issituated outside the case 40, is coupled to an external apparatus (orexternal circuit). Accordingly, the second area 212 is coupled to theexternal apparatus (or external circuit) through the P terminal 51,thereby serving as an outside connecting area.

It suffices for the second area 212 to have an area of sufficient sizefor the P terminal 51 to be connected. The second area 212 is seamlesslyconnected to the first area 211. The second area 212 may be formed nearan edge of the insulating substrate 10. FIG. 2 illustrates an example inwhich the second area 212 is formed near an edge 10 a of the insulatingsubstrate 10.

The O pad 22 is an electrode pattern (or interconnection pattern) foroutputting the output power (e.g., alternating voltage) of the powerconversion circuit 2. An example of the material of the O pad 22 iscopper. The O pad 22 includes a first area (second transistor mountingarea) 221, a second area 222, and a middle area 223. In FIG. 2, theboundary between the first area 221 and the middle area 223 and theboundary between the middle area 223 and the second area 222 are shownby dash-and-two-dot lines for illustrative purposes. This also appliesto other drawings (e.g., FIG. 1).

The first area 221 of the O pad 22 is the area on which the plurality ofsecond transistors Tr2 and the second diodes Di2 provided in one-to-onecorrespondence with the second transistors Tr2 are mounted. It sufficesfor the first area 221 to have an area of sufficient size for mountingthe plurality of second transistors Tr2 and the plurality of seconddiodes Di2 and for mounting interconnections in the case ofinterconnections (wirings) being provided by utilizing the first area221 as will be described later. The first area 221 is not limited to aparticular shape, and may be a quadrilateral such as a rectangle or asquare. The first area 221 is disposed at a spaced distance from thefirst area 211 of the P pad 21 in a predetermined direction (i.e., inthe X direction in FIG. 2).

Each second transistor Tr2 is mounted on the first area 221 such thatthe lower electrode DP and the first area 221 face each other, and areelectrically coupled to each other. Each second diode Di2 is mounted onthe first area 221 such that the cathode CP and the first area 221 faceeach other, and are electrically coupled to each other. The lowerelectrode DP and the cathode CP may be fixedly mounted to the first area221 through solder or sintered material, for example.

The arrangement of the second transistors Tr2 and the second diodes Di2on the first area 221 is not limited to a particular arrangement. Forexample, the plurality of second transistors Tr2 may be aligned in the Ydirection as illustrated in FIG. 2, and the second diodes Di2 may bedisposed alongside the respective second transistors Tr2 on the sidetoward the P pad 21.

The second area 222 of the O pad 22 is the area to which the O terminal(i.e., output terminal) 52 for outputting the output power of the powerconversion circuit 2 is coupled. One end of the O terminal 52 may befixedly mounted to the second area 222 through solder or sinteredmaterial, for example. The other end of the O terminal 52, which issituated outside the case 40, is coupled to an external apparatus (orexternal circuit). Accordingly, the second area 222 is coupled to theexternal apparatus (or external circuit) through the O terminal 52,thereby serving as an outside connecting area. It suffices for thesecond area 222 to have an area of sufficient size for the O terminal 52to be connected. The second area 222 may generally be formed near anedge of the insulating substrate 10. FIG. 2 illustrates an example inwhich the second area 222 is formed near an edge 10 b of the insulatingsubstrate 10 opposite the edge 10 a.

The middle area 223 is the area which connects the first area 221 andthe second area 222. The middle area 223 is seamlessly connected to thefirst area 221 and the second area 222. The middle area 223 may be partof the first area 221 or the second area 222.

The N pad 23 is an electrode pattern (or interconnection pattern) forsupplying negative power (e.g., negative voltage) to the powerconversion circuit 2. An example of the material of the N pad 23 iscopper. The N pad 23 includes a first area (absorbing device couplingarea) 231 and a second area 232. In FIG. 2, the boundary between thefirst area 231 and the second area 232 is shown by a dash-and-two-dotline for illustrative purposes. This also applies to other drawings(e.g., FIG. 1).

The first area 231, which is part of the N pad 23, is disposed at aspaced distance from the P pad 21 and the O pad 22, between the firstarea 211 of the P pad 21 and the first area 221 of the O pad 22, in aplane defined by the upper face of the insulating substrate 10 (i.e., ina plan view as viewed in the thickness direction of the insulatingsubstrate 10). The first area 231 of the N pad 23, which is situatedopposite the first area 211 of the P pad 21 and opposite the first area221 of the O pad 22, extends in a direction intersecting the direction(i.e., the X direction in FIG. 2) in which the first area 211 and thefirst area 221 are aligned. In FIG. 2, the first area 231 of the N pad23 extends along an edge 211 a of the first area 211 of the P pad 21 (oralong an edge 221 a of the first area 221 of the O pad 22).

The second area 232 of the N pad 23 is the area to which an N terminal(i.e., negative-side input terminal) 53 for supplying negative power tothe power conversion circuit 2 is coupled. One end of the N terminal 53may be fixedly mounted to the second area 232 through solder or sinteredmaterial, for example. The other end of the N terminal 53, which issituated outside the case 40, is coupled to an external apparatus (orexternal circuit). Accordingly, the second area 232 is coupled to theexternal apparatus (or external circuit) through the N terminal 53,thereby serving as an outside connecting area. It suffices for thesecond area 232 to have an area of sufficient size for the N terminal 53to be connected. The second area 232, which is seamless with the firstarea 231, is disposed near an edge of the insulating substrate 10, forexample. FIG. 2 illustrates an example in which the second area 232 isdisposed near the edge 10 a of the insulating substrate 10.

The first control pad 24 is an electrode pattern (or interconnectionpattern) to which a first control terminal 54 for supplying a controlsignal (i.e., gate signal or gate voltage) to the second upperelectrodes GP of the first transistors Tr1 is connected to, therebyserving as a gate pad. An example of the material of the first controlpad 24 is copper. One end of the first control terminal 54 may befixedly mounted to the first control pad 24 through solder or sinteredmaterial, for example. The other end of the first control terminal 54,which is situated outside the case 40, is coupled to an externalapparatus (or external circuit). Accordingly, the first control pad 24is electrically coupled to the external apparatus (or external circuit)through the first control terminal 54. It suffices for the first controlpad 24 to have an area of sufficient size for the first control terminal54 to be connected and also for interconnections (i.e., wirings) to beprovided, which will be described later. It suffices for the firstcontrol pad 24 to be disposed on the insulating substrate 10 such thatinterconnections to the second upper electrodes GP of the firsttransistors Tr1 are easily made. FIG. 2 illustrates an example in whichthe first control pad 24 is disposed near the edge 10 a of theinsulating substrate 10.

The second control pad 25 is an electrode pattern (or interconnectionpattern) to which a second control terminal 55 for supplying a controlsignal (i.e., gate signal or gate voltage) to the second upperelectrodes GP of the second transistors Tr2 is connected to, therebyserving as a gate pad. An example of the material of the second controlpad 25 is copper. One end of the second control terminal 55 may befixedly mounted to the second control pad 25 through solder or sinteredmaterial, for example. The other end of the second control terminal 55,which is situated outside the case 40, is coupled to an externalapparatus (or external circuit). Accordingly, the second control pad 25is electrically coupled to the external apparatus (or external circuit)through the second control terminal 55. It suffices for the secondcontrol pad 25 to have an area of sufficient size for the second controlterminal 55 to be connected and also for interconnections (i.e.,wirings) to be provided, which will be described later. It suffices forthe second control pad 25 to be disposed on the insulating substrate 10such that interconnections to the second upper electrodes GP of thesecond transistors Tr2 are easily made. FIG. 2 illustrates an example inwhich the second control pad 25 is disposed near the edge 10 b of theinsulating substrate 10.

The first auxiliary pad 26 is an electrode pattern (or interconnectionpattern) to which a first auxiliary terminal 56 for outputting thepotential of the first upper electrodes SP of the first transistors Tr1is connected. An example of the material of the first auxiliary pad 26is copper. One end of the first auxiliary terminal 56 may be fixedlymounted to the first auxiliary pad 26 through solder or sinteredmaterial, for example. The other end of the first auxiliary terminal 56,which is situated outside the case 40, is coupled to an externalapparatus (or external circuit). Accordingly, the first auxiliary pad 26is electrically coupled to the external apparatus (or external circuit)through the first auxiliary terminal 56. In the case of the first upperelectrode SP being a source electrode, the first auxiliary pad 26 servesas an upper-arm-side source pad of the semiconductor module 1. Thepotential of the first upper electrodes SP output from the firstauxiliary terminal 56 is utilized to generate a control signal that issupplied to the second upper electrodes GP of the first transistors Tr1,for example. It suffices for the first auxiliary pad 26 to be disposedon the insulating substrate 10 such that interconnections to the firstupper electrodes SP of the first transistors Tr1 are easily made. FIG. 2illustrates an example in which the first auxiliary pad 26 is disposednear the edge 10 a of the insulating substrate 10. It suffices for thefirst auxiliary pad 26 to have an area of sufficient size for the firstauxiliary terminal 56 to be connected and also for interconnections(i.e., wirings) to be provided, which will be described later.

The second auxiliary pad 27 is an electrode pattern (or interconnectionpattern) to which the second auxiliary terminal 57 for outputting thepotential of the first upper electrodes SP of the second transistors Tr2is connected. An example of the material of the second auxiliary pad 27is copper. One end of the second auxiliary terminal 57 may be fixedlymounted to the second auxiliary pad 27 through solder or sinteredmaterial, for example. The other end of the second auxiliary terminal57, which is situated outside the case 40, is coupled to an externalapparatus (or external circuit). Accordingly, the second auxiliary pad27 is electrically coupled to the external apparatus (or externalcircuit) through the second auxiliary terminal 57. In the case of theupper electrode SP being a source electrode, the second auxiliary pad 27serves as a lower-arm-side source pad of the semiconductor module 1. Thepotential of the first upper electrodes SP output from the secondauxiliary terminal 57 is utilized to generate a control signal that issupplied to the second upper electrodes GP of the second transistorsTr2, for example. It suffices for the second auxiliary pad 27 to bedisposed on the insulating substrate 10 such that interconnections tothe first upper electrodes SP (i.e., source electrodes) of the secondtransistors Tr2 are easily made. FIG. 2 illustrates an example in whichthe second auxiliary pad 27 is disposed near the edge 10 b of theinsulating substrate 10. It suffices for the second auxiliary pad 27 tohave an area of sufficient size for the second auxiliary terminal 57 tobe connected and also for interconnections (i.e., wirings) to beprovided, which will be described later.

The plurality of absorbing devices 30 are the devices which absorb asurge voltage in the power conversion circuit 2. An example of theabsorbing devices 30 is a condenser. An example of the condenser is aceramic condenser. It suffices for the condenser for surge absorbingpurposes to have a sufficient capacitance for absorbing an expectedsurge voltage. The absorbing devices 30 are connected to the first area211 of the P pad 21 at one end thereof, and are connected to the firstarea 231 of the N pad 23 at the other end thereof. The plurality ofabsorbing devices 30 are disposed at spaced intervals along thedirection in which the first area 231 extends. The number of absorbingdevices 30 may be equal to a number obtained by dividing the totalcapacitance required to absorb a surge voltage by the capacitance of asingle capacitor taking into account derating.

The P terminal 51, the O terminal 52, the N terminal 53, the firstcontrol terminal 54, the second control terminal 55, the first auxiliaryterminal 56, and the second auxiliary terminal 57 may be the constituentelements of the semiconductor module 1 when the semiconductor module 1is implemented as a configuration having the case 40.

In the following, electrical connections including interconnectionstructures in the semiconductor module 1 will be described by referringto FIG. 1 and FIG. 9. FIG. 9 is a drawing illustrating an equivalentcircuit of the semiconductor module 1. In FIG. 9, those elementscorresponding to the constituent elements of the semiconductor module 1are referred to by the same or similar reference characters. In FIG. 9,the absorbing devices 30 are illustrated as condensers. Thesemiconductor module 1 has interconnections placed therein such as toimplement the equivalent circuit illustrated in FIG. 9.

The lower electrodes DP of the first transistors Tr1 and the cathodes CPof the first diodes Di1 are electrically coupled to each other throughthe P pad 21, and the P pad 21 is connected to the P terminal 51.Accordingly, the lower electrodes DP of the first transistors Tr1 andthe cathodes CP of the first diodes Di1 are electrically coupled to theP terminal 51. Further, the first upper electrodes SP of the firsttransistors Tr1 are coupled through wires W1 to the respective anodes APof the first diodes Di1. In this manner, the first transistors Tr1 andthe first diodes Di1 are coupled in reverse parallel, with the firstdiodes Di1 serving as freewheeling diodes. Examples of the wires W1include wires, ribbons, etc. Examples of the material of the wires W1include copper, aluminum, etc. The number of wires W1 may be one, or maybe more than one.

The second upper electrode GP of the first transistors Tr1 are coupledto the first control pad 24 through wires W2. Examples of the wires W2include wires, ribbons, etc. Examples of the material of the wires W2include copper, aluminum, etc. Due to the fact that the first controlterminal 54 is coupled to the first control pad 24, the second upperelectrodes GP of the first transistors Tr1 are electrically coupled tothe first control terminal 54. A control signal can thus be appliedthrough the first control terminal 54 to the second upper electrodes GPof the first transistors Tr1.

The first upper electrodes SP of the first transistors Tr1 are alsocoupled to the first auxiliary pad 26 through wires W3. Examples of thewires W3 include wires, ribbons, etc. Examples of the material of thewires W3 include copper, aluminum, etc. Due to the fact that the firstauxiliary terminal 56 is coupled to the first auxiliary pad 26, thefirst upper electrodes SP of the first transistors Tr1 are electricallycoupled to the first auxiliary terminal 56. Accordingly, the potentialof the first upper electrodes SP of the first transistors Tr1 can beoutput through the first auxiliary terminal 56, and the output potentialcan be utilized to generate a control signal for controlling the firsttransistors Tr1.

The anodes AP of the first diodes Di1 are coupled to the O pad 22through wires W4. Accordingly, the first upper electrodes SP of thefirst transistors Tr1 are coupled to the O pad 22 through the anodes APof the first diodes Di1 and the wires W4. The plurality of firsttransistors Tr1 are thus electrically coupled in parallel. In theconfiguration illustrated in FIG. 1, the wires W4 are coupled at one endthereof to an area of the O pad 22 that is not the second area 222, forexample. Examples of the wires W4 include wires, ribbons, etc. Examplesof the material of the wires W4 include copper, aluminum, etc. Thenumber of wires W4 may be one, or may be more than one.

The lower electrodes DP of the second transistors Tr2 and the cathodesCP of the second diodes Di2 are electrically coupled to each otherthrough the O pad 22, and the O pad 22 is connected to the O terminal52. Accordingly, the lower electrodes DP of the second transistors Tr2and the cathodes CP of the second diodes Di2 are electrically coupled tothe O terminal 52. Further, the first upper electrodes SP of the secondtransistors Tr2 are coupled through wires W5 to the respective anodes APof the second diodes Di2. In this manner, the second transistors Tr2 andthe second diodes Di2 are coupled in reverse parallel, with the seconddiodes Di2 serving as freewheeling diodes. Examples of the wires W5include wires, ribbons, etc. Examples of the material of the wires W5include copper, aluminum, etc. The number of wires W5 may be one, or maybe more than one.

The second upper electrode GP of the second transistors Tr2 are coupledto the second control pad 25 through wires W6. Examples of the wires W6include wires, ribbons, etc. Examples of the material of the wires W6include copper, aluminum, etc. Due to the fact that the second controlterminal 55 is coupled to the second control pad 25, the second upperelectrodes GP of the second transistors Tr2 are electrically coupled tothe second control terminal 55. A control signal can thus be appliedthrough the second control terminal 55 to the second upper electrodes GPof the second transistors Tr2.

The first upper electrodes SP of the second transistors Tr2 are alsocoupled to the second auxiliary pad 27 through wires W7. Examples of thewires W7 include wires, ribbons, etc. Examples of the material of thewires W7 include copper, aluminum, etc. Due to the fact that the secondauxiliary terminal 57 is coupled to the second auxiliary pad 27, thefirst upper electrodes SP of the second transistors Tr2 are electricallycoupled to the second auxiliary terminal 57. Accordingly, the potentialof the first upper electrodes SP of the second transistors Tr2 can beoutput through the second auxiliary terminal 57, and the outputpotential can be utilized to generate a control signal for controllingthe second transistors Tr2.

The anodes AP of the second diodes Di2 are coupled to the N pad 23through wires W8. Examples of the wires W8 include wires, ribbons, etc.Examples of the material of the wires W8 include copper, aluminum, etc.The number of wires W8 may be one, or may be more than one. The wires W8are preferably arranged in parallel to the wires W4 in order to reduceparasitic inductance between the P pad 21 and the N pad 23 (namely,between the P terminal 51 and the N terminal 53) due to the effect ofmutual inductance. In the example illustrated in FIG. 1, the anodes APof the second diodes Di2 are coupled to the first area 231 of the N pad23 through the wires W8. Accordingly, the first upper electrodes SP ofthe second transistors Tr2 are coupled to the N pad 23 through theanodes AP of the second diodes Di2 and the wires W8. The plurality ofsecond transistors Tr2 are thus electrically coupled in parallel.

In the interconnection structure described above, the first upperelectrodes SP of the first transistors coupled in parallel areelectrically coupled to the O pad 22, and the lower electrodes DP of thesecond transistors Tr2 coupled in parallel are electrically coupled tothe O pad 22. Accordingly, the first upper electrodes SP of the firsttransistors Tr1 coupled in parallel are electrically coupled to thelower electrodes DP of the second transistors Tr2 coupled in parallel.Further, the lower electrodes DP of the first transistors Tr1 coupled inparallel are electrically coupled to the P terminal 51, and the firstupper electrodes SP of the second transistors Tr2 coupled in parallelare electrically coupled to the N terminal 53. Accordingly, asillustrated in FIG. 9, the group of first transistors Tr1 coupled inparallel and the group of second transistors Tr2 coupled in parallel areconnected in series between the P terminal 51 and the N terminal 53. Inthis manner, the configuration on the insulating substrate 10constitutes the power conversion circuit 2.

The absorbing devices 30 provide couplings between the first area 211 ofthe P pad 21 and the first area 231 of the N pad 23, which is situatedbetween the first area 211 of the P pad 21 and the first area 221 of theO pad 22. Further, the second transistors Tr2 and the first area 231having the absorbing devices 30 mounted thereon are electrically coupledto each other through the wires W8, the wires W5, and the second diodesDi2 mounted on the first area 221 of the O pad 22. With thisarrangement, the absorbing devices 30 are electrically coupled inparallel to the group of first transistors Tr1 constituting the upperarm and the group of second transistors Tr2 constituting the lower armwhich are electrically coupled in series between the P terminal 51 andthe N terminal 53 of the power conversion circuit 2.

In the configuration of the semiconductor module 1, control signals areapplied to the first transistors Tr1 and the second transistors Tr2through the first control terminal 54 and the second control terminal55, respectively, thereby alternately turning on and off the firsttransistors Tr1 and the second transistors Tr2. In this manner, thedirect-current power (e.g., direct-current voltage) applied between theP terminal 51 and the N terminal 53 is converted into alternate-currentpower (e.g., alternate-current voltage), which may be output through theO terminal 52.

In the power conversion circuit 2 including the first transistors Tr1and the second transistors Tr2 connected in series between the Pterminal 51 and the N terminal 53, surge voltage occurs when each of thefirst transistors Tr1 and the second transistors Tr2 is turned on oroff.

The size of surge voltage is calculated by L·di/dt when the current isdenoted as i, and the inductance is denoted as L. The inductance thatcontrols the size of surge voltage includes the wire inductance of thepath through which the current i flows. Further, di/dt depends on thespeed of switching of the first transistors Tr1 and the secondtransistors Tr2. As continuing efforts have been made to increase thespeed of switching, there is a tendency for di/dt to increase.Especially when a wide-bandgap semiconductor is used as the material forthe first transistors Tr1 and the second transistors Tr2, di/dt tends toincrease because the switching speed is faster than in the case of Si.In order to effectively reduce surge voltage, therefore, it is importantto reduce wire inductance included in the inductance L by placing theabsorbing devices 30 in close physical proximity (in terms of the lengthof electrical connections) to the first transistors Tr1 and to thesecond transistors Tr2.

In the semiconductor module 1, the N pad 23 has the first area 231 whichis situated between the first area 211 of the P pad 21 and the firstarea 221 of the O pad 22. The absorbing devices 30 are connected to thefirst area 231 of the N pad 23 and to the first area 211 of the P pad21. Further, the second transistors Tr2 and the first area 231 of the Npad 23 are electrically coupled to each other through the wires W8, thewires W5, and the second diodes Dig mounted on the first area 221 of theO pad 22.

In this configuration, the absorbing devices 30 are placed in closephysical proximity (in terms of the length of electrical connections) tothe first transistors Tr1 and the second transistors Tr2 performingswitching operations. As a result, the path of current flowing through aloop comprised of the first transistors Tr1, the second transistors Tr2,and the absorbing devices 30 has a small wire inductance when each ofthe first transistors Tr1 and the second transistors Tr2 is turned on oroff. Because of this, surge voltage is reduced, which stabilizes theelectric power (e.g., direct-current voltage) applied to the lowerelectrodes DP of the first transistors Tr1 and the first upperelectrodes SP of the second transistors Tr2 in the series circuitcomprised of the first transistors Tr1 and the second transistors Tr2.

In the semiconductor module 1, the group of first transistors Tr1coupled in parallel and the group of second transistors Tr2 coupled inparallel are connected in series. This arrangement enables a largecurrent to flow in the semiconductor module.

The semiconductor module 1 includes the plurality of first transistorsTr1 and the plurality of second transistors Tr2. Accordingly, the firstarea 211 having the first transistors Tr1 mounted thereon and the firstarea 221 having the second transistors Tr2 mounted thereon are largerthan the area required to mount a single first transistor Tr1 or asingle second transistor Tr2, for example.

Even when the first transistors Tr1 and the second transistors Tr2 aredisposed at spaced intervals in the first area 211 and the first area221, respectively, having a larger area as described above, theconfiguration of the semiconductor module 1 ensures that the wireinductances of the current paths from the first transistors Tr1 and thesecond transistors Tr2 to the absorbing devices 30 are low. Thisarrangement may effectively reduce surge voltage.

Moreover, the plurality of absorbing devices 30 are disposed at spacedintervals (or in a dispersed manner), so that each of the firsttransistors Tr1 and the second transistors Tr2 has at least oneabsorbing device 30, among the absorbing devices 30, situated in itsclose proximity. This results in the wire inductance being low withrespect to the current path extending from such an absorbing device 30to the corresponding one of the first transistors Tr1 and the secondtransistors Tr2, thereby reducing surge voltage more effectively. Whenthe first area 211 of the P pad 21 and the first area 221 of the O pad22 have a large area for mounting the plurality of first transistors Tr1and the plurality of second transistors Tr2, respectively, the pluralityof absorbing devices 30 disposed at spaced intervals can absorb surgevoltage in a distributed manner, thereby enabling further reduction ofsurge voltage.

<First Variation>

FIG. 4 is a schematic diagram of a semiconductor module 1A according toa first variation. FIG. 5 is a drawing schematically illustrating theconfiguration of the semiconductor module 1A on the insulating substrate10 illustrated in FIG. 4. In FIG. 5, the wires W1 through W8 are omittedfrom the illustration. The semiconductor module 1A differs from theconfiguration of the semiconductor module 1 mainly in that the N pad 23has a third area 233. The semiconductor module 1A will be described,with a focus on this difference.

As illustrated in FIG. 5, the third area 233 of the N pad 23 isconnected to an end of the first area 231 on the side opposite thesecond area 232, and is seamlessly connected with the first area 231.The area of the N pad 23 constituted by the first area 231 and the thirdarea 233 surrounds the first area 211 of the P pad 21. As illustrated asan example in FIG. 5, when the first area 211 is a rectangular shape,the third area 233 is arranged in parallel to an edge 211 b of the firstarea 211 of the P pad 21, and the area constituted by the first area 231and the third area 233 is a letter-L shape.

The third area 233 of the N pad 23 is coupled through the condensers Cto the first area 211 of the P pad 21 having the first transistors Tr1mounted thereon. The third area 233 serves as a condenser connectingarea. An example of the condensers C is a ceramic condenser. It sufficesfor the number of condensers C to be one or more.

As illustrated in FIG. 5, the configuration in which the N pad 23 hasthe third area 233 may have the second area 222 of the O pad 22extending along the third area 233. Namely, the second area 222 may beformed such as to have a portion overlapping the third area 233 of the Npad 23 and the first area 211 of the P pad 21 when viewed in the viewdirection parallel to the Y direction.

In the semiconductor module 1A, the plurality of first transistors Tr1are aligned at spaced intervals in the X direction as illustrated inFIG. 5. Due to the fact that the first control pad 24 and the firstauxiliary pad 26 are situated close to the edge 10 a of the insulatingsubstrate 10, the first transistors Tr1 are situated on the first area211 on the side toward the edge 10 a. In this case, each of the firstdiodes Di1 is situated alongside a corresponding one of the firsttransistors Tr1 in the Y direction. Due to the fact that the third area233 of the N pad 23 is situated close to the edge 10 b of the insulatingsubstrate 10, the first diodes Di1 are situated on the first area 211 onthe side toward the edge 10 b. It may be noted, however, that thearrangement of the plurality of first transistors Tr1 and the pluralityof second transistors Tr2 may alternatively be the same as in the caseof the semiconductor module 1 illustrated in FIG. 1 and FIG. 2.

The anodes AP of the first diodes Di1 are coupled to the second area 222of the O pad 22 through the wires W4 as illustrated in FIG. 4, forexample.

The semiconductor module 1A has at least the same effects and advantagesas the semiconductor module 1 because the N pad 23 has the first area231, and the first area 231 of the N pad 23 is electrically coupled tothe first area 211 of the P pad 21 through the absorbing devices 30. Dueto the fact that the third area 233 of the N pad 23 is coupled throughthe condensers C to the first area 211 of the P pad 21, potentialvariation at the P pad 21 may be reduced. This enables the stabilizationof power (e.g., voltage) applied to the lower electrodes DP of the firsttransistors Tr1. From this viewpoint, the condensers C may havecapacitances suitable for the stabilization of such a voltage.

<Second Variation>

FIG. 6 is a schematic diagram of a semiconductor module 1B according toa second variation. The semiconductor module 1B differs from theconfiguration of the semiconductor module 1A of the first variationmainly in that the N pad 23 further includes a fourth area (i.e.,condenser connecting area) 234. The semiconductor module 1B will bedescribed, with a focus on this difference. The interconnectionstructures for the plurality of first transistors Tr1 and the pluralityof second transistors Tr2 are the same as or similar to those of thefirst variation, and illustration of the wires W1 through W8 is omittedin FIG. 6.

The fourth area 234 of the N pad 23 is connected to an end of the thirdarea 233 opposite the first area 231, and is seamlessly connected withthe third area 233. The area of the N pad 23 constituted by the firstarea 231, the third area 233, and the fourth area 234 surrounds thefirst area 211 of the P pad 21. As illustrated as an example in FIG. 6,when the first area 211 is a rectangular shape, the fourth area 234 isarranged in parallel to an edge 211 c of the first area 211, and thearea constituted by the first area 231, the third area 233, and thefourth area 234 is a letter-U shape.

The fourth area 234 and the first area 211 are coupled through thecondensers C. It suffices for the number of condensers C to be one ormore.

The semiconductor module 1B has at least the same effects and advantagesas the semiconductor module 1A because the N pad 23 has the first area231, and the first area 211 of the P pad 21 is coupled through thecondensers C to the third area 233 and to the fourth area 234.

<Third Variation>

FIG. 7 is a schematic diagram of a semiconductor module 1C according toa third variation. FIG. 8 is a drawing schematically illustrating theconfiguration of the semiconductor module 1C on the insulating substrate10 illustrated in FIG. 7. In FIG. 8, the wires W1 through W8 are omittedfrom the illustration. The configuration of the semiconductor module 1Cdiffers from the semiconductor module 1A of the first variation mainlyin that a third auxiliary pad 28 and absorbing devices 30A are provided.The semiconductor module 1C will be described, with a focus on thisdifference.

The third auxiliary pad 28, which has a first area 281 and a second area282, serves as a floating pad. An example of the material of the thirdauxiliary pad 28 is copper. The first area 281 is situated between thefirst area 231 of the N pad 23 and the first area 211 of the P pad 21.The second area 282 is situated between the third area 233 of the N pad23 and the first area 211 of the P pad 21. The third auxiliary pad 28may have a similar shape to the area constituted by the first area 231and the third area 233 of the N pad 23.

The second area 282 of the third auxiliary pad 28 and the first area 211of the P pad 21 are coupled through condensers C1. The second area 282and the third area 233 of the N pad 23 are coupled through condensersC2. Accordingly, the first area 211 and the third area 233 areelectrically coupled through the condensers C1 and c2. This enables thestabilization of power (e.g., voltage) applied to the lower electrodesDP of the first transistors Tr1. It suffices for the condensers C1 andC2 to have capacitances enabling the stabilization of power (e.g.,voltage) applied to the lower electrodes DP of the first transistorsTr1.

The absorbing devices 30A includes first circuit elements 31 and secondcircuit elements 32. Both the first circuit elements 31 and the secondcircuit elements 32 are condensers. An example of condensers is aceramic condenser. It suffices for the condensers provided as the firstcircuit elements 31 and the second circuit elements 32 to have acapacitance capable of absorbing surge voltage. The first circuitelements 31 are connected to the first area 211 of the P pad 21 at oneend thereof, and are connected to the first area 281 of the thirdauxiliary pad 28 at the other end thereof. The second circuit elements32 are connected to the first area 281 of third auxiliary pad 28 at oneend thereof, and are connected to the first area 231 of the N pad 23 atthe other end thereof. With this arrangement, the first area 211 of theP pad 21 and the first area 231 of the N pad 23 are electrically coupledthrough the absorbing devices 30A.

In the semiconductor module 1C, the plurality of first transistors Tr1are aligned at spaced intervals in the X direction as illustrated inFIG. 8. Due to the fact that the first control pad 24 and the firstauxiliary pad 26 are situated close to the edge 10 a of the insulatingsubstrate 10, the first transistors Tr1 are situated on the first area211 on the side toward the edge 10 a. In this case, each of the firstdiodes Di1 is situated alongside a corresponding one of the firsttransistors Tr1 in the Y direction. Due to the fact that the third area233 is situated close to the edge 10 b of the insulating substrate 10,the first diodes Di1 are situated on the first area 211 on the sidetoward the edge 10 b. It may be noted, however, that the arrangement ofthe plurality of first transistors Tr1 and the plurality of secondtransistors Tr2 may alternatively be the same as in the case of thesemiconductor module 1 illustrated in FIG. 1 and FIG. 2.

The anodes AP of the first diodes Di1 are coupled to the second area 222of the O pad 22 through the wires W4 as illustrated in FIG. 4, forexample.

In the configuration of the semiconductor module 1C, the first area 211of the P pad 21 and the first area 281 of the third auxiliary pad 28 arecoupled to each other through the first circuit elements 31 asillustrated in FIG. 7 and FIG. 8. Further, the first area 281 of thethird auxiliary pad 28 and the first area 231 of the N pad 23 arecoupled to each other through the second circuit elements 32. With thisarrangement, the first area 211 of the P pad 21 and the first area 231of the N pad 23 are electrically coupled to each other through theabsorbing devices 30A including the first circuit elements 31 and thesecond circuit elements 32.

The semiconductor module 1C has at least the same effects and advantagesas the semiconductor module 1A because the N pad 23 has the first area231, and the first area 231 of the N pad 23 and the first area 211 ofthe P pad 21 are electrically coupled to each other through theabsorbing devices 30A.

A condenser having a large capacitance typically has a low withstandingvoltage. The fact that each of the absorbing devices 30A includes twoseries-connected condensers, i.e., the first circuit element 31 and thesecond circuit element 32, ensures that each condenser has a capacitancerequired to absorb surge voltage while having sufficient voltagetolerance as an absorbing device 30A. This is thus an effectiveconfiguration for the power semiconductor module 1C.

In the semiconductor module 1C, moreover, the first area 211 of the Ppad 21 and the third area 233 of the N pad 23 are electrically coupledthrough the condensers C1 and C2. This enables the stabilization ofpower (e.g., voltage) applied to the lower electrodes DP of the firsttransistors Tr1 as in the case of the semiconductor module 1A.

The disclosed example has been directed to the configuration in whichboth the first circuit element 31 and the second circuit element 32 arecondensers. Notwithstanding this, either one of the first circuitelement 31 and the second circuit element 32 may be a resistor. In thiscase, the absorbing device 30A serves as an RC circuit (or RC snubberelement). The resistor may be a printed thin-film resistor.

In the configuration of the semiconductor module 1C, one of thecondensers C1 and C2 may be replaced with a resistor.

According to the present disclosures, surge voltage is reduced morereliably.

Although the embodiments and variations of the disclosed technology haveheretofore been described, the present invention is not limited to thesevarious disclosed embodiments, and various modifications may be madewithout departing from the scope of the present invention.

The power conversion circuit is not limited to a single-phase powerconversion circuit such as a single-phase inverter circuit, and mayalternatively be a two-phase or three-phase power conversion circuit 2.The exemplary number of transistors and the exemplary number ofabsorbing devices are not limited to the numbers illustrated in thedrawings. The semiconductor module may have at least one firsttransistor and at least one second transistor. Similarly, thesemiconductor module may have at least one absorbing device.

The arrangement of the first transistors Tr1 and the second transistorsTr2 and the interconnection structures between the first transistorsTr1, the second transistors Tr2, and the various pads (i.e., the P pad,the N pad, the O pad, and the like) are not limited to those shown inthe examples, and are preferably optimized in such a manner as tominimize the wire inductance for the purpose of reducing surge voltage.

In the disclosed embodiments, a configuration in which the P pad 21 isthe positive-voltage side and the N pad 23 is the negative-voltage sidehas been described as an example. Alternatively, the pad 21 having thetransistors Tr1 mounted thereon may be the negative-voltage side, andthe pad 23 having no transistors mounted thereon may be thepositive-voltage side.

DESCRIPTION OF REFERENCE SYMBOLS

-   1, 1A, 1B, 1C . . . semiconductor module-   2 . . . power conversion circuit,-   10 . . . insulating substrate-   21 . . . P pad (first input interconnection pattern)-   22 . . . O pad (output interconnection pattern)-   23 . . . N pad (second input interconnection pattern)-   28 . . . third auxiliary pad (auxiliary interconnection pattern)-   30, 30A . . . absorbing device (surge voltage absorbing device)-   31 . . . first circuit elements-   32 . . . second circuit elements-   51 . . . P terminal (positive-side input terminal)-   52 . . . O terminal (output terminal)-   53 . . . N terminal (negative-side input terminal)-   211 . . . first area (first transistor mounting area)-   221 . . . first area (second transistor mounting area)-   231 . . . first area (absorbing device connecting area)-   233 . . . third area (condenser connecting area)-   234 . . . fourth area (condenser connecting area)

1. A semiconductor module including a power conversion circuit,comprising: an insulating substrate; a first transistor constituting anupper arm of the power conversion circuit; a second transistorconstituting a lower arm of the power conversion circuit andelectrically series-coupled to the first transistor; a first inputinterconnection pattern disposed on the insulating substrate and coupledto a positive-side input terminal for supplying positive power to thepower conversion circuit; a second input interconnection patterndisposed on the insulating substrate and coupled to a negative-sideinput terminal for supplying negative power to the power conversioncircuit; an output interconnection pattern disposed on the insulatingsubstrate and coupled to an output terminal for outputting output powerof the power conversion circuit; and an absorbing device configured toabsorb surge voltage in the power conversion circuit, wherein the firstinput interconnection pattern includes a first-transistor mounting areaon which the first transistor is mounted, wherein the outputinterconnection pattern includes a second-transistor mounting area onwhich the second transistor is mounted, wherein the second inputinterconnection pattern includes an absorbing-device connecting areathat is disposed between the first-transistor mounting area and thesecond-transistor mounting area, and wherein the absorbing-deviceconnecting area is electrically coupled to the first-transistor mountingarea through the absorbing device.
 2. The semiconductor module asclaimed in claim 1, wherein the second input interconnection patternincludes a condenser connecting area seamlessly connected to an end ofthe absorbing-device connecting area, wherein the absorbing-deviceconnecting area and the condenser connecting area are disposed on theinsulating substrate such as to surround the first-transistor mountingarea, and wherein the condenser connecting area is electrically coupledto the first-transistor mounting area through a condenser.
 3. Thesemiconductor module as claimed in claim 1, further comprising anauxiliary interconnection pattern disposed on the insulating substratebetween the absorbing-device connecting area and the first-transistormounting area, wherein the absorbing device includes a first circuitelement and a second circuit element, wherein the first circuit elementelectrically couple the auxiliary interconnection pattern and thefirst-transistor mounting area, and wherein the second circuit elementelectrically couple the auxiliary interconnection pattern and theabsorbing-device connecting area.
 4. The semiconductor module as claimedin claim 1, comprising: a plurality of said first transistors; and aplurality of said second transistors, wherein the plurality of firsttransistors are mounted on the first-transistor mounting area, and areelectrically coupled in parallel, and wherein the plurality of secondtransistors are mounted on the second-transistor mounting area, and areelectrically coupled in parallel, and
 5. The semiconductor module asclaimed in claim 1, comprising a plurality of said absorbing devices,wherein the plurality of absorbing devices are disposed at spacedintervals.
 6. A semiconductor module, comprising: an insulatingsubstrate; a first transistor constituting one of an upper arm and alower arm of a power conversion circuit; a second transistorconstituting another one of the upper arm and the lower arm of the powerconversion circuit; a first input interconnection pattern being a flatconductive plate disposed on the insulating substrate, the first inputinterconnection pattern having the first transistor mounted thereon andbeing electrically coupled to a first end of the first transistor; anoutput interconnection pattern being a flat conductive plate disposed onthe insulating substrate, the output interconnection pattern having thesecond transistor mounted thereon and being electrically coupled to afirst end of the second transistor; a second input interconnectionpattern disposed on the insulating substrate and arranged at a positionbetween the first input interconnection pattern and the outputinterconnection pattern; an interconnection electrically coupling asecond end of the first transistor and the output interconnectionpattern to each other; an interconnection electrically coupling a secondend of the second transistor and the second input interconnectionpattern to each other; and a capacitive device connected between thefirst input interconnection pattern and the second input interconnectionpattern.